Optical apparatus with a plurality of zooming control means

ABSTRACT

An imaging apparatus is disclosed which is integrally provided with two image pickup systems for respectively converting subject light into image signals and two displays for respectively displaying images relative to the image signals obtained by the two image pickup systems. In the disclosed imaging apparatus, since the operations of the two image pickup systems are synchronized, it is not necessary to insert an element, such as a prism, in each optical path. Further, since a common signal processing circuit is provided for performing predetermined processing of the image signals outputted from the two image pickup systems, the size of the imaging apparatus is reduced.

This application is a continuation, division, of application Ser. No.08/746,152, filed Nov. 6, 1996, U.S. Pat. No. 5,654 752, which is acontinuation of Ser. No. 08/394, 624, filed Feb. 27,1995, abandonedwhich is a division of Ser. No. 08/132,666, filed Oct. 6, 1993 (Pat. No.5,448, 294).

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an imaging apparatus and, moreparticularly, to an imaging apparatus provided with two image pickupmeans.

2. Description of the Related Art

As one example of this kind of imaging apparatus, an optical binoculartelescope has heretofore been known which can provide an observer asubject image having a visually preferable stereoscopic effect. Theoptical binocular telescope is arranged, for example, as shown in FIG.5. The arrangement shown in FIG. 5 includes objective lens systems 41aand 42a, rectangular prisms 42a, 42b, 43a and 43b for folding theirassociated optical paths and for converting their respective invertedimages into erecting images, eyepiece lens systems 44a, 44b, 45a, 45b,46a and 46b, and optical paths 47a and 47b of the respective opticalsystems.

As shown in FIG. 5, the optical paths of subject lights which passthrough the respective objective lens systems 41a and 41b are folded bythe rectangular prisms 42a and 43a and the rectangular prisms 42b and43b. Accordingly, it is possible to convert the respective invertedimages into erecting images, and it is also possible to reduce theoverall length of a lens barrel (not shown) without reducing the lengthsof the respective optical paths. The subject lights whose optical pathshave been folded by the rectangular prisms 43a and 43b respectivelyreach the observer's eyes through the eyepiece lens systems 44a, 45a,46a and 44b, 45b, 46b.

However, an optical binocular telescope, such as the above-describedrelated-art example, has a number of problems. For example, since it isdesirable that a subject image be observed with the naked eye as anerecting image, it is necessary to insert an element for converting aninverted image into an erecting image, for example, rectangular prismssuch as the above-described ones, between each objective lens and itsassociated eyepiece lens. Also, if the size of the binocular telescopeis to be reduced, it is necessary to reduce its lens barrel by insertingthe rectangular prisms or the like into each optical path and foldingthe optical path.

Further, it is difficult for the observer to confirm various informationas to photographing states, such as the magnification of the binoculartelescope, while viewing a subject image.

SUMMARY OF THE INVENTION

It is, therefore, an object of the present invention to solve theabove-described problems.

Another object of the present invention is to provide an imagingapparatus in which it is not necessary to insert an element, such as aprism, in an optical path.

To achieve the above-described objects, according to one aspect of thepresent invention, there is provided an imaging apparatus whichcomprises an apparatus body, two image pickup means for respectivelyconverting subject light into image signals, two display means forrespectively displaying images relative to the image signals obtained bythe two image pickup means, the two image pickup means and the twodisplay means being integrally provided in the apparatus body, andsynchronizing means for synchronizing operations of the respective twoimage pickup means.

The above and other objects, features and advantages of the presentinvention will become apparent from the following detailed descriptionof preferred embodiments of the present invention, taken in conjunctionwith the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing the arrangement of an imagingapparatus according to one embodiment of the present invention;

FIG. 2 is a block diagram showing the arrangement of an imagingapparatus according to another embodiment of the present invention;

FIG. 3 is a block diagram showing the arrangement of an imagingapparatus according to yet another embodiment of the present invention;

FIG. 4 is a block diagram showing an arrangement example of a combiningcircuit used in the apparatus shown in FIG. 3; and

FIG. 5 is a schematic view showing the arrangement of an opticalbinocular telescope according to a related art.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will be described belowin detail with reference to the accompanying drawings.

An imaging apparatus according to a first embodiment of the presentinvention will be described below with reference to FIG. 1.

FIG. 1 shows the first embodiment in which the present invention isapplied to an electronic binocular telescope of a type different fromthe above-described optical binocular telescope.

Referring to FIG. 1, a light image of a subject is enlarged at apredetermined magnification by a lens part 1a, and the enlarged lightimage passes through an infrared cut filter 2a or an infraredtransmission filter 2a'. The light image which has passed through theinfrared cut filter 2a or the infrared transmission filter 2a' isconverted into an electrical signal by an image pickup element 3a suchas a CCD. At this time, a driving pulse produced by a timing generatingcircuit 5 is supplied to a CCD driving circuit 4a and the CCD 3a isdriven by the output signal of the CCD driving circuit 4a. Incidentally,the CCD 3a is capable of effecting photoelectric conversion of not onlyan image of normal visible light but also an image of infrared light.The signal outputted from the CCD 3a is subjected to sample-and-holdprocessing in a sample-and-hold circuit 7a, and the output signal of thesample-and-hold circuit 7a is amplified at a predetermined gain by apreamplifier 8a. The output signal of the-preamplifier 8a is controlledby an automatic gain control amplifier (hereinafter referred to as the"AGC amplifier") 9a so that the level of the output signal of the AGCamplifier 9a is set to a predetermined level in accordance with thelevel of its input signal.

A light receiving element 21 receives a subject light to determine theluminance level of the subject light, thereby outputting a signalindicative of either one of two levels which correspond to light anddark, respectively. A filter controlling circuit 11a receives the outputsignal of the light receiving element 21 and outputs a control signal toa filter driving circuit 12a. The filter driving circuit 12a selects theinfrared cut filter 2a or the infrared transmission filter 2a' inaccordance with the control signal. In this manner, in the firstembodiment, if the output signal of the light receiving element 21 is ofthe "light" level, the infrared cut filter 2a is automatically selected,while if such output signal is of the "dark" level, the infraredtransmission filter 2a' is automatically selected.

The output signal of the AGC amplifier 9a is sent to a gamma correctioncircuit 10a or a gamma correction circuit 13a by a switch S1. The switchS1 is arranged to switch between a terminal "a" and a terminal "b" inresponse to the output signal of the light receiving element 21. If theoutput signal of the light receiving element 21 is of the "light" level,the switch S1 is connected to the terminal "b", while if such outputsignal is of the "dark" level, the switch S1 is connected to theterminal "a".

More specifically, if the luminance level of a subject is high, theinfrared cut filter 2a is employed, so that the input signal of the CCD3a contains no infrared component. Accordingly, similarly to signalprocessing for an image of normal visible light, the output signal ofthe AGC amplifier 9a is subjected to gamma correction in the gammacorrection circuit 13a, and the output signal of the gamma correctioncircuit 13a is subjected to white balance adjustment in a white balancecontrol circuit (hereinafter referred to as the "WB circuit") 14a.

If the luminance level of the subject is low, the infrared transmissionfilter 2a' is employed, so that the input signal of the CCD 3 containsan infrared component as well. Accordingly, the aforesaid normal signalprocessing is not performed. More specifically, the output signal of theAGC amplifier 9a is only subjected to gamma correction in the gammacorrection circuit 10a having a correction characteristic which issuited to signal processing for an image of infrared light, and WB(white balance) adjustment is not performed. This is because if a signalcontaining an infrared component is subjected to WB adjustment, thelevels of its color components (R, G, B) are adjusted to levels utterlydifferent from their respective actual levels.

A switch S2 selects the output signal of the gamma correction circuit10a or that of the WB circuit 14a on the basis of the output signal oflight receiving element 21 similarly to the switch S1, and outputs theselected signal.

The output signal of the switch S2 is converted from analog to digitalby an A/D conversion circuit 15a, and the digital signal is stored in abuffer memory 16a. The signal stored in the buffer memory 16a is readout and subjected to predetermined digital signal processing in adigital signal processor 17a. The output signal of the digital signalprocessor 17a is converted from digital to analog by a D/A conversioncircuit 18a. The output signal of the digital signal processor 17a isalso sent to an output terminal 22a, and is then outputted from theoutput terminal 22a to external equipment such as a digital VTR. At thistime, each of the elements 15a, 16a, 17a and 18a is controlled by acontrol signal supplied from a control part 6. The shown electronicbinocular telescope includes another signal processing system made up ofconstituent elements 1b to 18b similar to those of the above-describedsignal processing system. The constituent elements 1b to 18b performfunctions and operations similar to those of the respective constituentelements indicated by the corresponding reference numerals accompaniedby "a". Detailed description of the constituent elements 1b to 18b is,therefore, omitted.

The signals which have been converted from digital to analog by the D/Aconversion circuits 18a and 18b are respectively outputted to selectingswitches S5 and S6 and are also supplied to analog output terminals 31aand 31b, respectively. The selecting switches S5 and S6 are normallycontrolled by the control part 6 so that they are connected to theirterminals A. Thus, the output sign a of the CCD 3a is selected by theselecting switch S5, while the output signal of the CCD 3b is selectedby the selecting switch S6, and the selected signals are respectivelyoutputted from the selecting switches S5 and S6. The output signals ofthe respective selecting switches S5 and S6 are inputted to displaydevices 19 and 20, such as liquid crystal displays, and images relativeto the input signals are respectively displayed on the display devices19 and 20.

If the selecting switches S5 and S6 are connected to their respectiveterminals B, it is possible to display the image relative to the outputsignal of the CCD 3a on the liquid crystal display 20 and the imagerelative to the output signal of the CCD 3b on the liquid crystaldisplay 19. Also, if the selecting switch S5 is connected to theterminal A and the selecting switch S6 is connected to the terminal B,it is possible to display the image relative to the output signal of theCCD 3a on each of the liquid crystal displays 19 and 20. Also, if theselecting switch S5 is connected to the terminal B and the selectingswitch S6 is connected to the terminal A, it is possible to display theimage relative to the output signal of the CCD 3b on each of the liquidcrystal displays 19 and 20.

According to the first embodiment, since the electronic binoculartelescope having the above-described arrangement is realized, it is notnecessary to insert an element, such as a prism, in either of theoptical paths of the imaging apparatus. Further, it is possible toeasily perform processing such as the processing of effecting switchingbetween images displayed on the two liquid crystal displays 19 and 20 orthe processing of displaying an identical image on each of the liquidcrystal displays 19 and 20. It is also possible to easily realize areduction in the size of the imaging apparatus.

Further, when subject light is to pass through the filter 2a or 2a' andthe filter 2b or 2b' before reaching the CCDs 3a and 3b, the filters 2aand 2a'; 2b and 2b' are automatically interchanged according to theluminance of the subject and signal processing suited to the lighttransmitted through each of the selected filters is carried out.Accordingly, it is possible to provide an image which is more preferablein visual terms.

A second embodiment of the present invention will be described belowwith reference to FIG. 2.

FIG. 2 is a block diagram showing the arrangement of an imagingapparatus according the second embodiment of the present invention. InFIG. 2, the same reference numerals are used to denote constituentelements similar to those shown in FIG. 1, and detailed descriptionthereof is omitted.

The arrangement shown in FIG. 2 further includes variable angle prisms(VAPs) 23a and 23b. In each of the VAPs 23a and 23b, for example, thegap between two parallel flat glasses is charged with a liquid of highrefractive index and hermetically enclosed with a rubber bellows or thelike. Each of the VAPs 23a and 23b is arranged to vary its apex angle byvarying the angles of the parallel flat glasses, thereby enablingcorrection of an image shake.

A motion vector detecting circuit 27 obtains the motion vector of animage from a digital image signal outputted from the DSP (digital signalprocessor) 17a, thereby detecting an image shake. Then, the motionvector detecting circuit 27 outputs a control signal to a VAP drivingcircuit 25 to correct the image shake (to cancel the motion vector).Then, the VAP driving circuit 25 reads out data for correcting theoperational errors of the VAPs 23a and 23b which result from theirrespective individual differences, from a ROM 26 in which the data isstored in advance, applies the required correction to the controlsignal, and outputs the control signal to each actuator 24a and 24b. Theactuators 24a and 24b apply loads to the predetermined peripheralportions of the respective VAPs 23a and 23b to cause the correspondingoptical axes to incline laterally and horizontally, thereby correctingthe shakes of the associated optical images with respect to anydirection.

The subject lights which have been subjected to the image-shakecorrection by the respective VAPs 23a and 23b are converted intoelectrical signals by the CCDs 3a and 3b in the previously-describedmanner. The output signals of the CCDs 3a and 3b are supplied to aselecting switch S7. The selecting switch S7 switches to alternatelyoutput the output signals of the CCDs 3a and 3b to the next stage inaccordance with with a certain timing determined by the control part 6,for example, at intervals of 1/60 second. Thus, the output signals ofthe CCDs 3a and 3b are alternately outputted from the selecting switchS7 at intervals of 1/60 second.

Subsequently, the output signal of the selecting switch S7 passesthrough a signal processing system similar to that shown in FIG. 1 andis inputted to a selecting switch S8. The switching timing of theselecting switch S8 is normally synchronized with the switching timingof the selecting switch S7 which is determined by the control part 6.Accordingly, the output signal of the D/A conversion circuit 18a isclassified into the output signal of the CCD 3a and the output signal ofthe CCD 3b. Then, the output signal of the selecting switch S8 issupplied to either of the liquid crystal displays 19 and 20 and an imagerelative to the input signal of either of the display devices 19 and 20is displayed.

During this operation, the image signal is only supplied to each of theliquid crystal displays 19 and 20 at intervals of 1/60 second. However,since the liquid crystal displays 19 and 20 can hold their currentdisplayed images until the next image signals are supplied, the imageson the liquid crystal displays 19 and 20 are displayed withoutinterruption.

Also, by controlling the selecting switch S7 and the selecting switchS8, it is possible to arbitrarily display the images relative to theoutput signals of the CCDs 3a and 3b on the liquid crystal displays 19and 20.

For example, the selecting switch S7 and the selecting switch S8 may becontrolled so that the selecting S8 is connected to its terminal Bduring the interval that the selecting switch S7 is connected to itsterminal A, whereas the selecting switch S8 is connected to its terminalA during the interval that the selecting switch S7 is connected to itsterminal B. In this case, it is possible to display the image relativeto the output signal of the CCD 3a on the liquid crystal display 19 andthe image relative to the output signal of the CCD 3b on the liquidcrystal display 20. If the selecting switch S7 and the selecting switchS8 are connected to the respective terminals A, it is possible todisplay the image relative to the output signal of the CCD 3a on each ofthe liquid crystal displays 19 and 20 at the same time. If the selectingswitch S7 and the selecting switch S8 are connected to the respectiveterminals B, it is possible to display the image relative to the outputsignal of the CCD 3b on each of the liquid crystal displays 19 and 20 atthe same time.

In the second embodiment, the charge storage time of each of the CCDs 3aand 3b is selected to be 1/60 second, as described previously. However,the charge storage time can be arbitrarily set by means of an operatingpart 28. In other words, by varying the charge storage time of each ofthe CCDs 3a and 3b, it is possible to realize a so-called electronicshutter function. While the electronic shutter function is beingoperated, the switching timing of each of the selecting switches S5 andS6 is also varied according to the read-out timing of each of the CCDs3a and 3b.

The operating part 28 is also provided with a key (not shown) forturning on and off an image-shake preventing function, and an operatorcan specify whether to execute image-shake prevention, by operating thekey. The operating part 28 is further provided with a distance measuringkey, a magnification varying key and other keys as will be describedlater.

According to the arrangement of the second embodiment, not only is itpossible to achieve effects and advantages similar to those of the firstembodiment described above, but also it is possible to remarkably reducethe required circuit scale since the output signals of the respectiveCCDs 3a and 3b are processed by a common circuit.

Also, since the charge storage time of each of the CCDs 3a and 3b can bevaried, it is possible to provide an image of optimum luminance at alltimes by varying a shutter speed in accordance with the luminance of asubject.

Further, an image shake due to a camera shake can be corrected by theVAPs 23a and 23b, whereby it is possible to prevent a degradation inimage quality.

An imaging apparatus according to a third embodiment of the presentinvention will be described below with reference to FIG. 3.

FIG. 3 shows the third embodiment of the present invention. In FIG. 3,the same reference numerals are used to denote constituent elementssimilar to those shown in FIGS. 1 and 2, and detailed descriptionthereof is omitted.

The output signal of the switch S8 is sent to each of picture combiningcircuits 29 and 30. The picture combining circuits 29 and 30 arecontrolled by the control part 6 to normally output their input signalsto the respective liquid crystal displays 19 and 20 withoutmodification. If the operator operates the operating part 28 to selectthe function of displaying a subsidiary picture in combination withanother picture, a control signal for displaying a subsidiary picture incombination with another picture is outputted from the control part 6 toeach of the picture combining circuits 29 and 30. The picture combiningcircuits 29 and 30 which have received the control signal can displayone picture as a subsidiary picture in a picture displayed on each ofthe liquid crystal displays 19 and 20. For example, it is possible todisplay on the liquid crystal display 19 an image relative to the outputsignal of the CCD 3a as a primary picture and the output signal of theCCD 3b as a subsidiary picture.

It is also possible to display a distance to a subject as a subsidiarypicture by means of the arrangement shown in FIG. 3 by way of example.In the shown arrangement, there is provided a distance measuring part 24which is means capable of measuring a distance to a subject, and whenthe operator operates the distance measuring key of the operating part28, the control part 6 outputs a control signal for distance measurementto the distance measuring part 24. A distance information processingcircuit 25 converts distance information outputted from the distancemeasuring part 24 into a signal of a form which is suitably displayed onthe liquid crystal display 20, and outputs the signal to a picturecombining circuit 30. Then, the signal indicative of the distanceinformation is combined with the output signal of the CCD 3a or 3b bythe picture combining circuit 30 which has received the control signalfrom the control part 6. Thus, the distance to the subject is displayedon the liquid crystal display 20 as the subsidiary picture. Accordingly,an observer can know the distance to the subject while viewing an imagedisplayed in the binocular telescope. Although the distance informationis displayed on only the liquid crystal display 20, it is also possibleto display the distance information on the liquid crystal display 19 byoutputting the signal indicative of the distance information to thepicture combining circuit 29 as well and combining the signal in theabove-described manner.

Also, by operating a zooming operating key of the operating part 28, azooming motor 32 is driven via the control part 6 to move lens parts 1aand 1b, whereby the magnification of the subject image can be varied.

Further, by operating an operating key of the operating part 28, asignal indicative of the magnification of the binocular telescope and asignal indicative of the size of the subject obtained through acalculation performed by the control part 6 on the basis of themagnification or a signal indicative of the luminance, etc. of thesubject can be outputted to and combined with the subject image by thepicture combining circuit 30. Thus, it is possible to display thedistance information indicative of the distance to the subject, themagnification of the binocular telescope, the size of the subject, theluminance of the subject or other information in the subsidiary pictureon the liquid crystal display 20.

One example of either of the picture combining circuits 29 and 30 willbe described below with reference to FIG. 4. Referring to FIG. 4, aterminal 401 is an input terminal for inputting an image signal for theprimary picture, while a terminal 402 is an input terminal for inputtingan image signal for the subsidiary picture. The output signals from theCCDs 3a and 3b are appropriately selected by and inputted through theinput terminals 401 and 402, respectively. If the aforesaid distanceinformation, magnification and others are to be displayed, the outputsignal of the CCD 3a or 3b is inputted to the input terminal 401, whilethe signals indicative of the distance information, the magnificationand others are inputted to the input terminal 402. Selection from amongthe signals inputted to the input terminals 401 and 402 is performed bya switch part 400 which has received a control signal outputted from thecontrol part 6.

The signal inputted through the input terminal 401 is supplied to both aprimary image signal processing circuit 403 and a primary imagesynchronizing signal processing circuit 405, while the signal inputtedthrough the input terminal 402 is supplied to both a subsidiary imagesignal processing circuit 404 and a subsidiary image synchronizingsignal processing circuit 406. Synchronizing signals are formed from therespective input signals by the primary image synchronizing signalprocessing circuit 405 and the subsidiary image synchronizing signalprocessing circuit 406, and are outputted to a memory controllingcircuit 408. The output signal of the subsidiary image signal processingcircuit 404 is subjected to compression in a memory 407 so that thesubsidiary picture is compressed vertically and horizontally. Theseoperations are performed by executing low-speed writing to andhigh-speed reading from the memory 407 as well as address controlthereof under the control of the memory controlling circuit 408. Thewriting and the reading of the subsidiary image signal are synchronizedwith the primary image signal by the aforesaid synchronizing signal.

Thus, the output signal of the subsidiary image signal processingcircuit 404 is formed into an image signal indicative of a picture ofreduced size, and the image signal is combined with the output signal ofthe primary image signal processing circuit 403 by a signal switchingcircuit 409 as if the picture indicated by the image signal were fittedinto the picture indicated by the output signal of the primary imagesignal processing circuit 403. The resultant image signal is outputtedto the liquid crystal displays 19 and 20. Also, since the memorycontrolling circuit 408 receives the control signal from the controlpart 6 and performs writing to the memory 407, if the picture combiningfunction is inoperative, the primary image signal is outputted withoutmodification.

As is apparent from the above description, in accordance with the thirdembodiment, various useful information different from a subject imagecan be displayed in the subsidiary picture (or the primary picture) oneach of the liquid crystal displays 19 and 20.

Also, if the CCD driving circuits 4a and 4b of the timing generatingcircuit 5 is controlled to vary the readout timing of each of the CCDs3a and 3b so that the output signal therefrom is read out at intervalsof 1/120 second, i.e., half the aforesaid interval of 1/60 second, it ispossible to suppress a flicker occurring due to switching between theright and left images. In this case, it is preferable to vary theswitching timing of each of the selecting switches S7 and S8.

What is claimed is:
 1. An optical apparatus comprising:(a) a pluralityof optical systems for forming a plurality of optical images; (b) aplurality of image stabilizing means for respectively stabilizing saidimages; (c) drive means for driving said plurality of image stabilizingmeans; (d) compensation means for compensating a characteristicdifference between said plurality of image stabilizing means; and (e) aplurality of zooming means for respectively varying zooming conditionsof said plurality of optical images based on a common control signal. 2.An apparatus according to claim 1, wherein said plurality of opticalsystems comprises image display members.
 3. An apparatus according toclaim 1, wherein said plurality of optical systems comprises liquidcrystal display members.
 4. An apparatus according to claim 1, whereinsaid plurality of image stabilizing means includes a plurality ofoptical stabilizing members for respectively stabilizing said pluralityof images.
 5. An apparatus according to claim 4, wherein said pluralityof optical stabilizing members comprises a variable angle prism.
 6. Anapparatus according to claim 1, further comprising motion detectingmeans for detecting a motion of said apparatus.
 7. An apparatusaccording to claim 6, wherein said drive means drives said plurality ofimage stabilizing means according to an output of said motion detectingmeans.
 8. An apparatus according to claim 1, wherein said compensationmeans include a memory for compensating the characteristic differencebetween said plurality of image stabilizing means.
 9. An apparatusaccording to claim 1, wherein said plurality of optical systems, saidplurality of zooming means, said plurality of image stabilizing means,said drive means and said compensation means are integrally provided inan apparatus body.
 10. An apparatus according to claim 1, wherein saidoptical apparatus is a binocular.
 11. An apparatus according to claim 1,further comprising a plurality of viewing members.
 12. An apparatusaccording to claim 1, wherein said plurality of zooming means are drivenby a motor.
 13. An optical apparatus comprising:(a) a plurality ofoptical systems for forming a plurality of optical images; (b) aplurality of image stabilizing means for respectively stabilizing saidimages; (c) detection means for detecting a shake of said opticalapparatus and for forming a common detection signal; (d) drive means fordriving said plurality of image stabilizing means in response to saidcommon detection signal; (e) a mode switch for switching between a firstmode for activating said drive means and a second mode for deactivatingsaid drive means; and (f) a plurality of zooming means for respectivelyvarying zooming conditions of said plurality of optical images based ona common control signal.
 14. An apparatus according to claim 13, whereinsaid plurality of optical system comprises image display members.
 15. Anapparatus according to claim 13, wherein said plurality of opticalsystems comprises liquid crystal display members.
 16. An apparatusaccording to claim 13, wherein said plurality of image stabilizing meansincludes a plurality of optical stabilizing members for respectivelystabilizing said plurality of images.
 17. An apparatus according toclaim 16, wherein said plurality of optical stabilizing memberscomprises a variable angle prism.
 18. An apparatus according to claim13, wherein said detection means detects a motion of said apparatus. 19.An apparatus according to claim 13, further comprising compensationmeans for compensating a characteristic difference between saidplurality of image stabilizing means.
 20. An apparatus according toclaim 19, wherein said compensation means includes a memory forcompensating the characteristic difference between said plurality ofimage stabilizing means.
 21. An apparatus according to claim 19, whereinsaid plurality of optical systems, said mode switch, said plurality ofimage stabilizing means, said drive means and said detection means areintegrally provided in an apparatus body.
 22. An apparatus according toclaim 19, wherein said optical apparatus is a binocular.
 23. Anapparatus according to claim 13, further comprising a plurality ofviewing members.
 24. An apparatus according to claim 13, wherein saidmode switch is manually operable.